Spade bit

ABSTRACT

The drill bit comprises a cutting blade formed at one end of a shank. The cutting blade has a pair of cutting shoulders that extend inwardly from the outer sides of the blade toward the bit axis. A tip having converging sides that create a point extends from the shoulders. The cutting edge of each shoulder is beveled with respect to the plane of the face of the blade. A flute is provided on the leading portion of each blade face adjacent the cutting edges. Each flute is a smooth curve that creates a substantially uninterrupted recess on each face of the blade that facilitates chip removal, increases the drill rate and lowers the power required to drill a hole. A non-stick coating may be applied to the blade to further facilitate chip removal.

BACKGROUND

This invention relates generally to boring tools and more particularlyto so-called “spade bits,” which are typically used with a drill fordrilling holes in wood.

Spade bits are widely used for boring holes between approximately ¼″ and1½″ diameter in wood and similar soft materials, because they are fast,true cutting, resharpenable, and relatively inexpensive. Their namederives from the shape of the spadelike blade or cutter, in contrast tothe spiral shape of augers and twist drills. The blade, which is usuallyforged integrally from the shank, is relatively thin and flat and mayhave a width several times the diameter of the shank.

One known spade bit is disclosed in U.S. Pat. No. 4,682,917. A partialcross-section of this drill bit is shown drilling a bore in FIG. 6. Thisbit 11 includes a blade 3 shoulder flute 5 adjacent the cutting edge ofeach shoulder. The flute has a cross-sectional configuration having aninner surface portion 7 and an outer surface portion 9 where the outerportion and inner portion consist of planar surfaces that meet at anangle. The shoulder flutes preferably do not extend all the way to theouter sides of the blade but rather stop inwardly of the sides of theblade.

The inventor of the present drill bit determined that because thesurface portions 7 and 9 comprise substantially planar surfaces thatmeet at a relatively sharp angle, the approximate path of travel ofchips generated by this bit is as shown by the arrows in FIG. 8.Specifically the chips curl up face 9 until they strike face 7 at whichpoint they are reflected at a relatively severe angle almostperpendicular to the direction of travel of the bit, represented byarrow C. The chips are trapped in the bore 13 where they are swirledaround by the drill bit blade 3 as the drill bit rotates until the chipsare eventually ejected from the bore.

It has been determined that moving the chips within the bore 13 by blade3 slows the drilling rate and requires energy. Thus, not only is thedrilling rate slower than optimal, the amount of energy used to drillthe bore is increased. The use of excess energy to drill the bore canpresent a significant issue because many drills are battery powered suchthat the need for additional energy adversely affects the charge life ofthe battery resulting in the need for more frequent battery charges.

Thus, there is a need in the art for a bit that increases the drillingrate and that requires less power.

SUMMARY OF PREFERRED EMBODIMENTS OF THE INVENTION

The drill bit of the invention comprises a cutting blade formed at oneend of a shank. The cutting blade has a pair of cutting shoulders thatextend inwardly from the outer sides of the blade toward the bit axis. Atip having converging sides that meet at a point extends from theshoulders. The cutting edge of each shoulder is beveled with respect tothe plane of the face of the blade. A flute is provided on the leadingportion of each blade face adjacent the cutting edges. Each flute is asmooth curve that creates an uninterrupted recess on each face of theblade that facilitates chip removal, increases the drill rate and lowersthe power required to drill a hole. A non-stick coating may be appliedto the blade to further facilitate chip removal.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a plan view of one embodiment of the drill bit of theinvention.

FIG. 2 is a side view of the drill bit of FIG. 1.

FIG. 3 is an enlarged side view of the drill bit of FIG. 2.

FIG. 4 is an end view of the bit of FIG. 1.

FIG. 5 is an enlarged partial section view of one embodiment of thedrill bit of the invention.

FIG. 6 is a partial section view showing the drill bit of the inventiondrilling a bore.

FIG. 7 is a plan view of another embodiment of the drill bit of theinvention.

FIG. 8 is a partial section view of a prior art bit drilling a bore.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

Referring more particularly to the drawings the drill bit of theinvention is shown generally at 1 and consists of a shaft 2 having a hexconnection 4 formed at one end thereof for engaging a chuck of a drillsuch as an electric or battery operated hand tool. The hex connection 4may be formed with a recess 6 to be engaged by the quick-coupling of thedrill chuck as is known in the art. The shaft 2 is connected to acutting blade 8 having a first cutting face 10 and a second cutting face12 where the blade is connected to the shaft with a taper angle a ofapproximately 2°. Specifically, each face of the blade 10, tapers fromthe axis of rotation of the blade A-A approximately 1° such that theangle between the faces is approximately 2°. The 2° taper provides aslightly thicker shaft thereby increasing the strength of the drill bitover conventional configurations. A hole 25 may be provided to hang thedrill bit for storage. While the 2° taper is one preferred embodiment,the faces may be made parallel to one another such that the taper angleis 0°.

The blade 8 has a pair of shoulders 14 and 16 that form cutting edges 18and 20, respectively. The outer side edges 22 and 24 of blade 8 arespaced from one another approximately the diameter of the desired hole.The side edges are formed with a taper such that the blade 8 is widernear the shoulders 14 and 16 than it is near the shaft 2 byapproximately 0.01 inches to provide clearance to allow the blade topass through the material being drilled. The outer side edges 22 and 24are also formed with a side bevel 13 of approximately 7°-9° to allow theblade to clear the hole being drilled as the blade rotates as best shownin FIG. 4.

Referring to FIG. 4, the cutting edges 18 and 20 are on the leadingedges of the blade 8 as the blade rotates in the direction of arrow A.The cutting edges 18 and 20 are formed, in part, by beveling theshoulders as best shown in FIG. 3 to create an acute angle p between theshoulders and the plane of the face of the blade. In one embodimentbevel angle p is 12° to 22° with a preferred angle of 15° to 18°.

A tip 26, having converging sides 28 and 30, extends from betweenshoulders 14 and 16. The sides 28 and 30 of point 26 meet at point 32.In one embodiment a pyramid-type point is created where surfaces 42 and44 are formed in the tip such that the point is comprised of foursurfaces meeting at a point. Tip 26 has cutting edges 29 and 31 formedat the leading edges thereof. Spurs 46 and 48 are formed at the ends ofshoulders 14 and 16. Spurs 46 and 48 score and cut the periphery of thebore to create a clean cut line.

Adjacent to and forming part of each cutting edge 18 and 20 are flutes50 and 52, respectively, that facilitate the removal of chips from thebore, increase the drilling rate and decrease the power required todrill the bore. The flutes 50 and 52 define a surface that has a smoothprofile with no sharp corners or flat surfaces that impede chip flow outof the bore being drilled. In one embodiment the flutes extendapproximately 0.45 inches from the cutting edge or at least one quarterof the length of the blade.

Flutes 50 and 52 may be made identical such that specific reference ismade to flute 50 in FIG. 5 where flute 50 is a curved surface formed ofcurves with two different radii. The first curved surface 54 is formedas a curved surface with a radius of curvature of r₁ and extends fromthe cutting edge 18 to a point where the radius is substantiallyperpendicular to the surface 10 of the blade 8. The first curved surface54, where it intersects shoulder 14, defines cutting edge 18. Thesmaller the radius of curvature r₁ of this surface, the sharper thecutting edge 18. In one embodiment the radius r₁ is between 0.292 and0.692 inches with a preferred radius of 0.492 inches. The second curvedsurface 56 is formed with a radius of curvature of r₂ and extends fromthe end of the first curved surface to surface 10 of blade 8. Radius r₂is, in one embodiment, twice radius r₁ and is between 0.784 and 1.184inches with a preferred radius of 0.984 inches. Curved surfaces 54 and56 are arranged such that surface 54 is tangential to surface 56 suchthat the flute 50 is smooth with no pronounced surface interruptions.

The flutes 50 and 52 are arranged such that they extend laterally fromapproximately the axis A-A of the blade 8 to and through the outersurfaces 22 and 24, respectively. Because the flutes extend to the edgesof the blade, manufacture of the blade is simplified. Specifically, abasic blade form can be made such as by a stamping process where thewidth of the blade form exceeds the width of a range of finished blades.The blade form can then be trimmed to the desired width. This is to becompared to the situation where the flute terminates internally of theedge of the blade such that each finished blade width must be based on ablade form that is specifically manufactured to that width.

In one embodiment the flutes 50 and 52 extend into the bladeapproximately half the thickness of the blade. While the flutes areshown as two curved surfaces having different radii of curvature, theflutes may be made of a curve having a constant radius of curvature.Moreover the flutes may be made of more than two surfaces havingdifferent radii of curvature. For example a third surface having a thirdsmaller radius of curvature could be formed between surface 54 andcutting edge 18 to create a cutting edge having a sharper edge. In suchan arrangement the third curved surface would be arranged tangential tosurface 54. Likewise an additional curve having a larger radius ofcurvature may be used that is arranged tangential to surface 56.

The operation of the drill bit of the invention will be described withreference to FIG. 6 where drill bit 1 is shown drilling bore 60. Ascutting edges 18 and 20 engage the bottom of bore 60 chips are developedthat flow in the direction of the arrows. Specifically the chips contactsurface 50 and are projected substantially parallel to the direction ofmovement of drill bit 1 (represented by arrow D) and propelled out ofbore 60. Because flutes 50 and 52 are substantially smooth and are notformed with angles or other surface protrusions, the chips can flowsubstantially parallel to the axis of the drill and are quickly ejectedfrom the bore. Because the chips are quickly ejected from bore 60, theyare not swirled in the bore by blade 8. As a result, more of the powerused to rotate the blade is used for drilling, rather than being used tomove the chips in the bore. Thus, the drill of the invention drills at afaster rate and uses less power. Because the blade uses less power, itcan increase the charge life of a typical battery powered drill.

Another embodiment of the drill bit of the invention is shown in FIG. 7and is similar to bit 1 of FIGS. 1 through 6, where like referencenumerals are used to identify like components in the embodimentillustrated in FIG. 7. The blade is coated with a non-stick coating 62to further enhance the ability of the blade to eject chips from the borebeing drilled. In one embodiment the flutes 50 and 52 are covered withthe non-stick coating. The coating may be a powdered coat paint thatincludes non-stick powder such as TEFLON O. The coating may be sprayedon or dipped. The coating may be a thermoplastic that is applied inpowder form and then heated to melt onto the blade. Alternatively, thecoating may be a thermal set powder that is applied in powder form andheated where the heat creates a chemical reaction that bonds the coatingto the metal blade. While the non-stick coating is shown applied to theflutes, the coating may be applied to other portions of the bladeincluding the entire blade 8.

Specific embodiments of an invention are disclosed herein. One ofordinary skill in the art will recognize that the invention has otherapplications in other environments. Many embodiments are possible.

1.-19. (canceled)
 20. A drill bit comprising: a shaft: a blade attachedto the shaft; a cutting edge formed on the blade; a smooth flute formedin the blade adjacent the cutting edge; and a non-stick surface on theblade.
 21. The drill bit of claim 17 wherein the non-stick surface is onthe flute.
 22. The drill bit of claim 17 wherein the non-stick surfaceis only on the flute.
 23. The drill bit of claim 17 wherein thenon-stick surface includes TEFLON.
 24. The drill bit of claim 17 whereinthe non-stick surface is a powdered paint.
 25. The drill bit of claim 17wherein the non-stick surface is sprayed on the blade.
 26. The drill bitof claim 17 wherein the non-stick surface is a thermoplastic.